Fluid-structural analysis of modular floating solar farms under wave motion
Floating solar farms (FSFs) are emerging to be a viable option for large scale solar power production. The present study develops an original approach for the design assessment of the maximum stress/strain and displacement of massively connected modular FSFs under wave action. The scope includes two...
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sg-ntu-dr.10356-1624452022-10-19T05:02:16Z Fluid-structural analysis of modular floating solar farms under wave motion Sree, Dharma K. K. Law, Adrian Wing-Keung Pang, Dawn Sok Cheng Tan, Sze Tiong Wang, Chien Looi Kew, Jernice Huiling Seow, Wei Kiong Lim, Vincent Han School of Civil and Environmental Engineering Nanyang Environment and Water Research Institute Environmental Process Modelling Centre Engineering::Environmental engineering Floating Solar Farms Connected Floating Modules Floating solar farms (FSFs) are emerging to be a viable option for large scale solar power production. The present study develops an original approach for the design assessment of the maximum stress/strain and displacement of massively connected modular FSFs under wave action. The scope includes two parts: (1) numerical simulations for the fluid structural analysis with two-way coupling of a global array of connected modular floaters that hold the massive number of solar panels; and (2) experimental validation of the numerical predictions for the dynamic response of the global array under wave action. The numerical approaches are based on finite element simulations. Both static and dynamic simulations are carried out with and without using the Fluid Structure Interaction (FSI) method, under different incident wave characteristics, rheological properties of the global array, and mooring configurations. The experiments were performed with a flexible perforated sheet using Froude scaling for dynamic similitude, with ultrasonic measurements to quantify the wave profile as well as the displacement responses of the array under wave action. The comparison shows reasonable agreement between the predictions and measurements at discrete locations along the array. Finally, a summary is provided on how the new approach can aid in the design assessment of modular FSFs under wave motion. Housing & Development Board This work is supported by Housing & Development Board (HDB), Singapore under the research project “Study, analysis and development of numerical models for floating structures” (Contract No: L/059/20). 2022-10-19T05:02:16Z 2022-10-19T05:02:16Z 2022 Journal Article Sree, D. K. K., Law, A. W., Pang, D. S. C., Tan, S. T., Wang, C. L., Kew, J. H., Seow, W. K. & Lim, V. H. (2022). Fluid-structural analysis of modular floating solar farms under wave motion. Solar Energy, 233, 161-181. https://dx.doi.org/10.1016/j.solener.2022.01.017 0038-092X https://hdl.handle.net/10356/162445 10.1016/j.solener.2022.01.017 2-s2.0-85123120321 233 161 181 en L/059/20 Solar Energy © 2022 International Solar Energy Society. Published by Elsevier Ltd. All rights reserved. |
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Engineering::Environmental engineering Floating Solar Farms Connected Floating Modules |
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Engineering::Environmental engineering Floating Solar Farms Connected Floating Modules Sree, Dharma K. K. Law, Adrian Wing-Keung Pang, Dawn Sok Cheng Tan, Sze Tiong Wang, Chien Looi Kew, Jernice Huiling Seow, Wei Kiong Lim, Vincent Han Fluid-structural analysis of modular floating solar farms under wave motion |
| description |
Floating solar farms (FSFs) are emerging to be a viable option for large scale solar power production. The present study develops an original approach for the design assessment of the maximum stress/strain and displacement of massively connected modular FSFs under wave action. The scope includes two parts: (1) numerical simulations for the fluid structural analysis with two-way coupling of a global array of connected modular floaters that hold the massive number of solar panels; and (2) experimental validation of the numerical predictions for the dynamic response of the global array under wave action. The numerical approaches are based on finite element simulations. Both static and dynamic simulations are carried out with and without using the Fluid Structure Interaction (FSI) method, under different incident wave characteristics, rheological properties of the global array, and mooring configurations. The experiments were performed with a flexible perforated sheet using Froude scaling for dynamic similitude, with ultrasonic measurements to quantify the wave profile as well as the displacement responses of the array under wave action. The comparison shows reasonable agreement between the predictions and measurements at discrete locations along the array. Finally, a summary is provided on how the new approach can aid in the design assessment of modular FSFs under wave motion. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Sree, Dharma K. K. Law, Adrian Wing-Keung Pang, Dawn Sok Cheng Tan, Sze Tiong Wang, Chien Looi Kew, Jernice Huiling Seow, Wei Kiong Lim, Vincent Han |
| format |
Article |
| author |
Sree, Dharma K. K. Law, Adrian Wing-Keung Pang, Dawn Sok Cheng Tan, Sze Tiong Wang, Chien Looi Kew, Jernice Huiling Seow, Wei Kiong Lim, Vincent Han |
| author_sort |
Sree, Dharma K. K. |
| title |
Fluid-structural analysis of modular floating solar farms under wave motion |
| title_short |
Fluid-structural analysis of modular floating solar farms under wave motion |
| title_full |
Fluid-structural analysis of modular floating solar farms under wave motion |
| title_fullStr |
Fluid-structural analysis of modular floating solar farms under wave motion |
| title_full_unstemmed |
Fluid-structural analysis of modular floating solar farms under wave motion |
| title_sort |
fluid-structural analysis of modular floating solar farms under wave motion |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/162445 |
| _version_ |
1749179212823003136 |